EP1780529A1 - Dispositif de mesure des molécules et procédé de mesure des molécules - Google Patents

Dispositif de mesure des molécules et procédé de mesure des molécules Download PDF

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Publication number
EP1780529A1
EP1780529A1 EP05758240A EP05758240A EP1780529A1 EP 1780529 A1 EP1780529 A1 EP 1780529A1 EP 05758240 A EP05758240 A EP 05758240A EP 05758240 A EP05758240 A EP 05758240A EP 1780529 A1 EP1780529 A1 EP 1780529A1
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EP
European Patent Office
Prior art keywords
molecule
substrate
cantilever
probe
measuring apparatus
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EP05758240A
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German (de)
English (en)
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EP1780529A4 (fr
Inventor
Takaharu Okajima
Hiroshi Tokumoto
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Hokkaido University NUC
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Hokkaido University NUC
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Publication date
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Publication of EP1780529A1 publication Critical patent/EP1780529A1/fr
Publication of EP1780529A4 publication Critical patent/EP1780529A4/fr
Withdrawn legal-status Critical Current

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01QSCANNING-PROBE TECHNIQUES OR APPARATUS; APPLICATIONS OF SCANNING-PROBE TECHNIQUES, e.g. SCANNING PROBE MICROSCOPY [SPM]
    • G01Q60/00Particular types of SPM [Scanning Probe Microscopy] or microscopes; Essential components thereof
    • G01Q60/24AFM [Atomic Force Microscopy] or apparatus therefor, e.g. AFM probes
    • G01Q60/38Probes, their manufacture, or their related instrumentation, e.g. holders
    • G01Q60/42Functionalisation
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B82NANOTECHNOLOGY
    • B82YSPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
    • B82Y35/00Methods or apparatus for measurement or analysis of nanostructures

Definitions

  • the present invention relates to a molecule measuring apparatus and a molecule measuring method. More particularly, the present invention relates to molecule measurement using the atomic force microscope.
  • the atomic force microscope (hereinafter "AFM”), developed in 1986 (see non-patent document 1), is the kind of microscope that enables high resolution observation of the surface structures of conductors, semiconductors and insulators (including polymers and biomaterials).
  • AFM atomic force microscope
  • the single-molecule measuring method also called “force spectroscopy”
  • the inter-molecular interaction intermolecular bonding strength
  • the intra-molecular interaction conformation change of a single molecule
  • the conventional single-molecule measuring method is the kind of technique of sandwiching a macromolecule between a probe and a substrate and extending the molecule in a single axis direction.
  • the molecule is extended with respect to one direction of three axes (x, z and Y axes) of the fine motion displacement element of the apparatus (apparatus with the substrate, for example, an Atomic Force Microscope).
  • apparatus apparatus with the substrate, for example, an Atomic Force Microscope
  • the control method of extending the molecule by fixing velocity of the single-axis motion or the force acting in the single-axis direction.
  • the conventional single-molecule measuring method is therefore not an accurate extending technology in a single-axis direction. Furthermore, since the position drift is inevitable with the atomic force microscope, it is difficult to extend a single molecule continuously in a long time. Furthermore, with the conventional single-molecule measuring method, how the molecule peels off the substrate (the point where the molecule peels off the substrate) or the shape of the molecule on the substrate, cannot be measured.
  • the molecule measuring apparatus of the present invention may employ a configuration having: a lifting section that lifts an edge of a molecule existing on a substrate; and a control section that controls a peeling point of the molecule and a position of a lifting section to be on a vertical line with respect to the substrate, the peeling point being a boundary between a part where the molecule contacts with the substrate and a part where the molecule is detached from the substrate by means of the lifting section.
  • a molecule can be measured by controlling the extending direction of the molecule in a single axis direction. Especially, in measurement whereby a molecule on the substrate is extended or contracted, the extending direction of the molecule peeling off the substrate can be controlled by using the three-axis fine motion systems mutually vertically crossing.
  • “Lifting section” is a means for lifting an edge of a molecule on the substrate.
  • the lifting section there is a means which is used in a measuring method of deforming the molecule, for example, a cantilever, a glass needle, an light radiation pressure (optical pipette) and the like.
  • the glass needle is a glass stick having the tip thereof processed into a thin, needle shape.
  • a cantilever will be explained as an example of a lifting section. However, things other than the cantilever are by no means excluded.
  • the lifting section has a tip (tip portion, for example, the probe of the cantilever) for lifting an edge of a molecule.
  • Cantilever has a probe with a sharp tip attached to an edge (edge portion) of a soft lever.
  • the cantilever lifts a sample from the substrate by the tip of the probe.
  • the cantilever when the cantilever is mentioned, it includes the probe, unless otherwise specified. However, when the function of the probe needs to be clarified, the probe will be specifically mentioned (for example, the probe of the cantilever).
  • Amount of deflection is correspondent to the force working on the lifting section in the vertical direction (z-axis) with respect to the apparatus, and is measured by the apparatus.
  • the apparatus here is a molecule measuring apparatus which controls the lifting section.
  • the apparatus is an atomic force microscope. Note that, in this description, explanations will be given on the assumption that the plane of the apparatus (the plane formed by the x and y axes controlled by the apparatus) is parallel to the plane of the substrate where the sample exists (the plane formed by the x and y axes of the substrate) . Actually, although there are cases where the plane of the apparatus is not parallel to the plane of the substrate, the error caused by this situation can be usually ignored. Furthermore, with the optical tweezers method, a particle adhered to a molecule (for example, latex) is trapped by means of light. The gap of the displacement of the trapped particle corresponds to the amount of deflection.
  • “Molecule” in this description is the target substance (sample) of measurement.
  • a polymer chain macromolecule
  • the molecule is the kind of molecule where the force in the vertical direction monotonously increases with increasing the distance of the same radius direction from the center of the peeling point, r.
  • the target sample is the molecule, which behaves as a worm-like chain (WLC) (described later).
  • “Peeling point” is the boundary between the part where the molecule contacts with the substrate and the part where the molecule is detached from the substrate by being lifted. Above mentioned “by being lifted” means that the molecule is lifted by being extended, or that the molecule is lifted by means of a lifting section.
  • the space where the molecule is operated is represented by the coordinate space specified by three axes, that is, by the x, y and z axes. It is a premise that the coordinate space is determined by the molecule measuring apparatus. It is also a premise that the x and y axes form the plane of the apparatus or the substrate and the z-axis is vertical to the plane of the substrate.
  • the atomic force microscope and the AFM will be used synonymously.
  • the atomic force microscope is an example of molecule measuring apparatus.
  • Single-axis extension means that, when the molecule measuring apparatus (for example, the probe of the cantilever of the atomic force microscope) or the experimenter pulls a certain substance (sample), the direction of the pull (extended direction) and the direction in which the substance is deformed, (displacement vector) are always on the same axis. It also means that, in extension measurement, the vector connecting one edge fixed by the probe and the peeling point fixed on the substrate is always on the same axis (parallel to the z-axis).
  • Non-single-axis extension means a state where single-axis extension does not apply.
  • “Elasticity measurement” means examination of the relationship between tension working on a certain substance (sample) and its displacement.
  • the distance between both ends of the molecule moved by the apparatus or the experimenter corresponds to the distance between both ends of the molecule. Therefore, elasticity of the molecule can be accurately measured from the measurement the force and the displacement of the molecule measuring apparatus).
  • the displacement of the molecule measuring apparatus controlled by the experimenter does not correspond to the displacement of the molecule, and so the elasticity can not be accurately evaluated .
  • the evaluation is possible if the shape of the extended molecule is known.
  • the measured force does not match the tension working on the molecule.
  • the measurable quantities in the case of single molecule measurement are "the displacement of the molecule measuring apparatus (for example, the atomic force microscope) " and "the force in the vertical direction with respect to the substrate.”
  • the displacement of the molecule measuring apparatus is the distance between the substrate and the tip of the lifting section , and "the force in the vertical direction with respect to the substrate” is correspondent to the amount of deflection of the lifting section. Since “the displacement of the molecule measuring apparatus” is the displacement of the apparatus, the single-axis extending measurement is preferable in order to conform the displacement of the molecule measuring apparatus to the displacement of the molecule.
  • the lifting section (the position of the lifting section) is controlled (moved)"
  • the positional relationship between the lifting section and the molecule (the peeling point) is controlled to assure single-axis extension.
  • control is implemented such that the positional relationship between the lifting section and the molecule (the peeling point) is vertical with respect to the substrate.
  • FIG.1 shows an example of operation of extending a molecule by the single-axis extension in an embodiment of the present invention.
  • explanation will be given using an atomic force microscope as an example of a molecule measuring apparatus.
  • an edge of a random molecule (chain macromolecule) 900 existing on substrate 100 is pinched and lifted by cantilever 200 by physisorption (physical adsorption), covalent bond and so on.
  • physisorption physical adsorption
  • the position where molecule 900 peels off substrate 100 (the peeling point) and the position of the probe of cantilever 200 (that is, the relative positions of the peeling point and the probe) are controlled so that the force working on cantilever 200 in the vertical direction (z-axis direction) with respect to the plane of substrate 100, (an x-y plane) decreases.
  • cantilever 200 in the state of lifting an edge of molecule 900 and the peeling point where molecule 900 is detached from substrate 100 are on a vertical line with respect to substrate 100, and the positions of cantilever 200 and the peeling point are controlled while keeping the distance between cantilever 200 and substrate 100 (the shortest distance parallel with respect to the z-axis, corresponding to the length of the straight line connecting cantilever 200 and the peeling point) constant.
  • the probe moves on the plane parallel to substrate 100, which crosses the point of coordinates of the z-axis when molecule 900 is lifted, and searches the point where the amount of deflection is minimum.
  • Schematic diagram 910 shows an example of a schematic diagram of contour lines representing the magnitude of force in the vertical direction (z-axis direction) when cantilever 200, extending molecule 900, is moved within the plane (an x-y plane).
  • the minimum point in schematic diagram 910 corresponds to the peeling point of the molecule.
  • FIG.2 shows an example of an operation of extending the molecule by non-single-axis extension.
  • the direction of the pull (extended direction) and the direction in which the substance is deformed (displacement vector) are not on the same axis.
  • the AFM is equipped with a scanner of three axes by the x, y and z axes, which enables spatial position control in the precision of nanometers . Since the spatial coordinates (x, y and z axes) are determined by the AFM, it can be stated that the apparatus (AFM itself) is the reference position.
  • substrate 100 is placed on the x-y plane and the distance between the probe and substrate 100 is changed.
  • the molecule moves on a single axis (z-axis), and so it can be stated that "the molecule is extended in a single axis direction with respect to the apparatus as the reference position.” This situation does not pose any problems in the elasticity measurement of bulk-surface (substance uniformly dispersed on a surface). However, as shown in FIGs.1 and 2, when the chain macromolecule existing on the surface is regarded as the reference, it cannot be stated that single-axis extension is carried out.
  • Accurate single axis extension means that the molecule is extended always parallel to the extending axis (z-axis) and vertical with respect to the x-y plane. That is, in the conventional single molecule extending method, since cantilever 200 moves on a single axis (the cantilever moves in the vertical direction from the point where the molecule begins peeling off) as shown in FIG.2, the molecule is not extended by single axis extension.
  • FIG.3 schematically shows an example of operation flow of single axis extension.
  • a substance connecting four springs having a length of b is supposed.
  • the series spring shown in FIG.3 is an imaginary substance. It is expected that the molecule actually peels off in consecutive units (although discontinuous in atomic levels), and the model shown in FIG . 3 is different from the actual chain molecule.
  • the x-axis which corresponds to one direction on substrate 100, forms the plane of substrate 100 together with the y-axis .
  • the string-like molecule (peeling part) can be extended in a single axis direction by changing the extension position of the probe of cantilever 200 on the x-y plane (on substrate 100).
  • the track of the movement of the probe of cantilever 200 matches the adsorbing shape of molecule 900 by moving the position of the probe of cantilever 200 to the peeling point. Therefore, the measurement of the molecule can be performed without imaging the shape of molecule 900.
  • FIG.3 although an explanation was given using a model of a plurality of springs, the present invention is by no means limited to the substance where individual springs are discrete of one another as shown in FIG.3, and continuous substance and substance that cannot be divided into individual parts (hard to divide) are by no means excluded.
  • WLC model worm-like chain
  • molecule 900 when the force in the vertical (z-axis) direction is F z and the distance of the same radius direction, where the peeling point is the center, is r, a molecule fulfilling the condition ⁇ F z / ⁇ r > 0 is the target, and the WLC model is an example of the molecule.
  • FIG.4 shows an example of the relationship between the tension of molecule 900 and the extended length.
  • L (not shown) is the full length of molecule 900
  • L 0 is the distance between the tip of the probe and substrate 100
  • R is the straight distance between an edge of molecule 900 and the peeling point
  • is the angle formed by the z-axis and the probe of cantilever 200.
  • F z is the force working on cantilever 200 (corresponding to the amount of deflection: the force working in the vertical direction with respect to substrate 100).
  • a condition is considered that an edge of chain molecule 900 having a full length of L, is pulled by angle ⁇ up to the position of the height L 0 from substrate 100 by using the probe of cantilever 200 and the peeling point contacts with substrate 100.
  • Equation 1 f ( R ) K B ⁇ T ⁇ 1 4 ⁇ 1 - R L - 2 - 1 4 + R L
  • FIGs.5 and 6 show examples of change of F z with respect to ⁇ at different L 0 's.
  • the vertical axis is f (R) ⁇ cos ⁇ /K B T, and f(R)cos ⁇ is the force working in the z-axis direction.
  • the vertical axis is standardized as F z ( ⁇ /K B T).
  • ⁇ /K B T may be considered a constant.
  • F z is a monotonous increasing function of ⁇ .
  • FIG.7 shows an example of the configuration of the molecule measuring apparatus.
  • an atomic force microscope is supposed.
  • substrate 100 On substrate 100, a sample is placed. The sample may be placed in a solvent as well. Substrate 100 is a plane defined by the x and y axes.
  • Cantilever 200 lifts the sample.
  • Cantilever 200 has a probe with a sharp tip, and the tip portion of the probe becomes the contact point with an edge of the sample.
  • FIG.7 an example in which cantilever 200 is fixed is shown.
  • Computer 300 which controls scanner 500 and inputs information measured by photo-detector 700, reads the amount of deflection from the inputted information and sends feedback to scanner 500 based on the amount of deflection.
  • Monitor 400 displays data transmitted from computer 300 in graphical representation.
  • Substrate 100 is provided in scanner 500.
  • Scanner 500 moves substrate 100 in the x, y and z axis directions.
  • Scanner 500 is controlled by computer 300 and moves substrate 100.
  • Laser apparatus 600 irradiates a laser light to cantilever 200.
  • Photo-detector 700 receives the laser light reflected from the back of cantilever 200 and outputs information obtained from the received laser light to computer 300.
  • the laser light is illustrated by dotted lines.
  • Control section 510 includes measurement judging section 511, deflection amount storage section 512, measurement point storage section 513 and probe control section 514.
  • Measurement judging section 511 obtains the amount of deflection of cantilever 200 read from information measured by photo-detector 700, compares the obtained amount of deflection with the amount of deflection which measured earlier, detects the minimum value and judges whether or not to move the probe and measure the amount of deflection.
  • Deflection amount storage section 512 stores the measured amount of deflection and position information where the amount of deflection is measured. With respect to the measured amount of deflection, the amount of deflection of a predetermined number of amounts of deflection--for example, a number of amounts of deflection within a predetermined range used for extracting a minimum value--are stored.
  • the position information is information that specifies the position of the probe when the amount of deflection was measured.
  • the measurement point storage section 513 moves the probe from a given point to the measurement point (measurement range, information for specifying a relative position from a certain position) and stores the measurement point.
  • the user of the molecule measuring apparatus stores the measurement point in measurement point storage section 513 in advance. For example, a plurality of measurement points used in measuring the amount of deflection by moving the probe from a certain position are stored. It is expected that the measurement points exist within a predetermined circle or rectangle.
  • Probe control section 514 instructs scanner 500 to move cantilever 200 and controls the position of the probe.
  • FIG.9 is a flowchart showing an example of an operation of measuring the molecule.
  • control section 510 will be mainly explained.
  • the probe of cantilever 200 adsorbs (or combines) molecule 900 arranged on substrate 100 and lifts the molecule from substrate 100 (step S11) .
  • the upper parts in FIGs . 1 and 2 indicate the stage where the probe adsorbs molecule 900, and the lower part in FIG. 2 indicates the stage where molecule 900 is lifted from substrate 100.
  • the molecule measuring apparatus measures the amount of deflection of cantilever 200. In this stage in measurement, since the load (initial load) generated in the adsorption of the probe with substrate 100 is reflected in the amount of deflection, the amount of deflection after exceeding a predetermined extension length is regarded as the measurement value.
  • the measured amount of deflection is inputted to measurement judging section 511 of control section 510 together with the measured position information (step S12).
  • Measurement judging section 511 stores the amount of deflection and the position information into deflection amount storage section 512. Next, measurement judging section 511 outputs an instruction for moving the probe to the measurement point stored in the measurement point storage section 513 to probe control section 514, which controls scanner 500 based on the above instruction (step S13). Although a plurality of measurement points are stored in measurement point storage section 513, in what order these points are moved is determined in advance.
  • measurement judging section 511 obtains the amount of deflection after moving the probe and then stores that amount of deflection into deflection amount storage section 512 (step S14). Measurement judging section 511 judges whether the amount of deflection is measured for the above plurality of measurement points (step S15). If all the measurement points have not been measured (NO in step S15), the processes from the step S13 will be repeated. If all the measurement points have been measured (YES in step S15), measurement judging section 511 extracts the minimum value from the measured amounts of deflection (step S16) and moves the probe to the position of the minimum value, through probe control section 514 (step S17).
  • Measurement judging section 511 judges whether the amount of deflection for each measurement point is within a predetermined range (step S18).
  • the predetermined range is held in measurement judging section 511.
  • the processes from the step S13 will be repeated.
  • a waiting state will continue after a predetermined time passes or until an event occurs (step S19). The result upon arriving at S19 is shown in the illustration in lower part of FIG.1.
  • FIG. 9 If the flow of operations in FIG. 9 is the movement of the probe, the state of upper part in FIG.1 or FIG.2 shifts to the state of lower part of FIG.2 and further shifts to the state of lower part in FIG.1.
  • cantilever 200 it is preferable to move cantilever 200 on the plane of radius r which vertically crosses with the z-axis, as shown in FIG.4. Therefore, after the probe is once moved to a specific coordinate point of the z-axis, the coordinates on the x and y axes are changed to detect a position where the amount of deflection is smaller, without changing the z-axis coordinate.
  • the minimum value of the amount of deflection of cantilever 200 is detected, and the probe can be moved to the point where molecule 900 peels off substrate 100.
  • a method and apparatus can be provided whereby single-axis extension of a substance can be performed and the shape of the substance can be learned by utilizing the force in the z-axis direction, without observing the shape of a string-like (chain-like) substance.
  • the single-axis extension of a molecule can be performed at all times for the substrate and the probe, the accuracy of the measurement of the single molecule measuring method improves (improvement in accuracy of the single molecule measuring method).
  • the position of the probe since the position of the probe always matches the point where the molecule starts peeling off the substrate (initially, it is the point where the probe contacts with the substrate), the shape of the molecule before peeling from the position of the probe, the length of the peeled molecule (if the mass of the molecule is known, the length or weight of the unpeeled part) can be known, and the adsorption force or changes in adsorption/removability over time can be known from the movement of the initial point (acquisition of position information necessary in molecule operations).
  • These molecular spatial information which become basic information in the translation/rotation operation of the molecule, can be utilized in manufacturing molecular wires.
  • a lever the lever itself is made from a flexible material and is flexible
  • a probe with a sharp tip attached to an end thereof, such as cantilever 200 is provided;
  • the tip of the probe can pull a sample from the substrate by adsorbing (contacting and combining) with the sample;
  • the force working on the lever can be measured; and
  • the position of the lever can be precisely adjusted.
  • the present invention can be basically utilized for an apparatus which extends the molecule in terms of the single-axis as found in an optical tweezers method or a method using a glass needle, as a single-molecule extending method.
  • the processes of S13 to S18 in FIG.9 can be implemented by a program (control executed by a control processing section).
  • the program may be loaded to computer 300 and executed using a storage area under the control of a central processing unit (CPU) .
  • the above program may be stored in a recording medium.
  • the molecule measuring apparatus and molecule measuring method according to the present invention provide high accuracy and are suitable for use in high resolution measuring methods for nano-measuring apparatus for polymeric materials, basic technologies in molecule operations, drift measurement for apparatus at nano-levels, and technologies required in measuring chain polymers at single molecule levels for a long time.

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  • Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
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EP05758240A 2004-07-30 2005-07-08 Dispositif de mesure des molécules et procédé de mesure des molécules Withdrawn EP1780529A4 (fr)

Applications Claiming Priority (2)

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JP2004224573 2004-07-30
PCT/JP2005/012689 WO2006011348A1 (fr) 2004-07-30 2005-07-08 Dispositif de mesure des molécules et procédé de mesure des molécules

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JP4734653B2 (ja) * 2004-09-09 2011-07-27 国立大学法人北海道大学 ゲル基板材料を用いた分子測定装置および分子測定方法
CN113436777B (zh) * 2021-08-27 2022-01-14 之江实验室 基于探针的双向电泳力光阱起支方法及装置与应用

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JP4475478B2 (ja) 1999-12-07 2010-06-09 セイコーインスツル株式会社 遺伝子解析方法及び装置
US6677697B2 (en) * 2001-12-06 2004-01-13 Veeco Instruments Inc. Force scanning probe microscope

Non-Patent Citations (3)

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Title
ECKEL R ET AL: "Identification of binding mechanism in single molecule-DNA complexes", BIOPHYSICAL JOURNAL, BIOPHYSICAL SOCIETY, US, vol. 85, no. 3, 1 September 2003 (2003-09-01), pages 1968-1973, XP002475022, ISSN: 0006-3495 *
KELLERMAYER M S Z ET AL: "Folding-unfolding transitions in single titin molecules characterized with laser tweezers", SCIENCE, AMERICAN ASSOCIATION FOR THE ADVANCEMENT OF SCIENCE, WASHINGTON, DC; US, vol. 276, 16 May 1997 (1997-05-16), pages 1112-1116, XP002118923, ISSN: 0036-8075, DOI: 10.1126/SCIENCE.276.5315.1112 *
See also references of WO2006011348A1 *

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EP1780529A4 (fr) 2011-11-09
US7752897B2 (en) 2010-07-13
JP4852759B2 (ja) 2012-01-11
JPWO2006011348A1 (ja) 2008-05-01
WO2006011348A1 (fr) 2006-02-02

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